Show the following function is increasing
If $x<y$ is it true that
$x^{frac{1}{2n+1}}<y^{frac{1}{2n+1}}$?
I considered the following function $f(x)=x^{frac{1}{2n+1}}$
I computed $f^{'}(x)={frac{1}{2n+1}}x^{frac{-2n}{2n+1}}$
Now $x^{frac{-2n}{2n+1}}=(frac{1}{x^2})^{frac{n}{2n+1}}$
Note that $frac{1}{x^2} $ is always positive.
But how to show that $f^{'}(x)$ is positive because we are taking root?
Please help.
real-analysis calculus
asked Dec 9 at 7:15
Join_PhD
1968
add a comment |
If $x<y$ is it true that
$x^{frac{1}{2n+1}}<y^{frac{1}{2n+1}}$?
I considered the following function $f(x)=x^{frac{1}{2n+1}}$
I computed $f^{'}(x)={frac{1}{2n+1}}x^{frac{-2n}{2n+1}}$
Now $x^{frac{-2n}{2n+1}}=(frac{1}{x^2})^{frac{n}{2n+1}}$
Note that $frac{1}{x^2} $ is always positive.
But how to show that $f^{'}(x)$ is positive because we are taking root?
Please help.
real-analysis calculus
asked Dec 9 at 7:15
Join_PhD
1968
If $frac{1}{2n + 1}$ is a constant you might find it easier just to call that $t$ or something.
– Trevor Gunn
Dec 9 at 7:18
@TrevorGunn;How would that help?
– Join_PhD
Dec 9 at 7:19
Then you're less focused on the having a fraction in your exponent and you can think about the general properties of $x^t$ where $0 < t < 1$.
– Trevor Gunn
Dec 9 at 7:22
Is $x$ assumed to be positive? And what variable denotes $n$?
– Dr. Sonnhard Graubner
Dec 9 at 9:37
X is a real number and n is constant natural number
– Join_PhD
Dec 9 at 9:43
add a comment |
If $x<y$ is it true that
$x^{frac{1}{2n+1}}<y^{frac{1}{2n+1}}$?
I considered the following function $f(x)=x^{frac{1}{2n+1}}$
I computed $f^{'}(x)={frac{1}{2n+1}}x^{frac{-2n}{2n+1}}$
Now $x^{frac{-2n}{2n+1}}=(frac{1}{x^2})^{frac{n}{2n+1}}$
Note that $frac{1}{x^2} $ is always positive.
But how to show that $f^{'}(x)$ is positive because we are taking root?
Please help.
real-analysis calculus
asked Dec 9 at 7:15
Join_PhD
1968
If $x<y$ is it true that
$x^{frac{1}{2n+1}}<y^{frac{1}{2n+1}}$?
I considered the following function $f(x)=x^{frac{1}{2n+1}}$
I computed $f^{'}(x)={frac{1}{2n+1}}x^{frac{-2n}{2n+1}}$
Now $x^{frac{-2n}{2n+1}}=(frac{1}{x^2})^{frac{n}{2n+1}}$
Note that $frac{1}{x^2} $ is always positive.
But how to show that $f^{'}(x)$ is positive because we are taking root?
Please help.
real-analysis calculus
real-analysis calculus
asked Dec 9 at 7:15
Join_PhD
1968
asked Dec 9 at 7:15
Join_PhD
1968
asked Dec 9 at 7:15
Join_PhD
1968
asked Dec 9 at 7:15
Join_PhD
1968
asked Dec 9 at 7:15
Join_PhD
1968
1968
If $frac{1}{2n + 1}$ is a constant you might find it easier just to call that $t$ or something.
– Trevor Gunn
Dec 9 at 7:18
@TrevorGunn;How would that help?
– Join_PhD
Dec 9 at 7:19
Then you're less focused on the having a fraction in your exponent and you can think about the general properties of $x^t$ where $0 < t < 1$.
– Trevor Gunn
Dec 9 at 7:22
Is $x$ assumed to be positive? And what variable denotes $n$?
– Dr. Sonnhard Graubner
Dec 9 at 9:37
X is a real number and n is constant natural number
– Join_PhD
Dec 9 at 9:43
add a comment |
If $frac{1}{2n + 1}$ is a constant you might find it easier just to call that $t$ or something.
– Trevor Gunn
Dec 9 at 7:18
@TrevorGunn;How would that help?
– Join_PhD
Dec 9 at 7:19
Then you're less focused on the having a fraction in your exponent and you can think about the general properties of $x^t$ where $0 < t < 1$.
– Trevor Gunn
Dec 9 at 7:22
Is $x$ assumed to be positive? And what variable denotes $n$?
– Dr. Sonnhard Graubner
Dec 9 at 9:37
X is a real number and n is constant natural number
– Join_PhD
Dec 9 at 9:43
If $frac{1}{2n + 1}$ is a constant you might find it easier just to call that $t$ or something.
– Trevor Gunn
Dec 9 at 7:18
If $frac{1}{2n + 1}$ is a constant you might find it easier just to call that $t$ or something.
– Trevor Gunn
Dec 9 at 7:18
@TrevorGunn;How would that help?
– Join_PhD
Dec 9 at 7:19
@TrevorGunn;How would that help?
– Join_PhD
Dec 9 at 7:19
Then you're less focused on the having a fraction in your exponent and you can think about the general properties of $x^t$ where $0 < t < 1$.
– Trevor Gunn
Dec 9 at 7:22
Then you're less focused on the having a fraction in your exponent and you can think about the general properties of $x^t$ where $0 < t < 1$.
– Trevor Gunn
Dec 9 at 7:22
Is $x$ assumed to be positive? And what variable denotes $n$?
– Dr. Sonnhard Graubner
Dec 9 at 9:37
Is $x$ assumed to be positive? And what variable denotes $n$?
– Dr. Sonnhard Graubner
Dec 9 at 9:37
X is a real number and n is constant natural number
– Join_PhD
Dec 9 at 9:43
X is a real number and n is constant natural number
– Join_PhD
Dec 9 at 9:43
add a comment |
2 Answers
2
active
oldest
votes
One way of doing this is to use the elementary fact that inverse of any bijective (strictly) increasing function is (strictly) increasing. Note that $x^{2n+1}$ has positive derivative and it is bijective. Its inverse is your function $f$.
[ If $g$ is strictly incerasing, $x<y$ and $g^{-1}(x) geq g^{-1}(y)$ then $g(g^{-1}(x)) geq (g^{-1}(y))$ which is a contradiction. Hence $g^{-1}(x) < g^{-1}(y)$].
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
add a comment |
As you recognised, the claim is true if and only if $f_n(x):=x^{1/(2n+1)}$ is monotonously increasing. However this is not true. For the sake of convenience set $m=1/(2n+1)$, then
$$frac{d}{dx}f_n(x)=mx^{m-1}$$
which needs to be always positive for $f_n$ to be monotonously increasing. Let's restrict the domain to $(0,infty)$ to avoid complications with negative powers. Note that anywhere in this domain, $x$ raised to anything is always positive, hence $f_n'$ is positive iff $m$ is. So let's pick $m=-1$ (corresponding to $n=-1$) or any negative number to achieve $f_n'<0$ for all $x$, at which point we get $f_{-1}(x)=1/x$, a decreasing function on $(0,infty)$. Thus the problem condition is true exactly when $m>0$; or in other words, $n>0$.
Edit: in the comments you said that $ninmathbb N$, which of course implies $n>0$. Hence, the claim is true.
answered Dec 9 at 12:18
YiFan
2,4391421
add a comment |
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2 Answers
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2 Answers
2
active
oldest
votes
active
oldest
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active
oldest
votes
One way of doing this is to use the elementary fact that inverse of any bijective (strictly) increasing function is (strictly) increasing. Note that $x^{2n+1}$ has positive derivative and it is bijective. Its inverse is your function $f$.
[ If $g$ is strictly incerasing, $x<y$ and $g^{-1}(x) geq g^{-1}(y)$ then $g(g^{-1}(x)) geq (g^{-1}(y))$ which is a contradiction. Hence $g^{-1}(x) < g^{-1}(y)$].
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
add a comment |
One way of doing this is to use the elementary fact that inverse of any bijective (strictly) increasing function is (strictly) increasing. Note that $x^{2n+1}$ has positive derivative and it is bijective. Its inverse is your function $f$.
[ If $g$ is strictly incerasing, $x<y$ and $g^{-1}(x) geq g^{-1}(y)$ then $g(g^{-1}(x)) geq (g^{-1}(y))$ which is a contradiction. Hence $g^{-1}(x) < g^{-1}(y)$].
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
add a comment |
One way of doing this is to use the elementary fact that inverse of any bijective (strictly) increasing function is (strictly) increasing. Note that $x^{2n+1}$ has positive derivative and it is bijective. Its inverse is your function $f$.
[ If $g$ is strictly incerasing, $x<y$ and $g^{-1}(x) geq g^{-1}(y)$ then $g(g^{-1}(x)) geq (g^{-1}(y))$ which is a contradiction. Hence $g^{-1}(x) < g^{-1}(y)$].
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
One way of doing this is to use the elementary fact that inverse of any bijective (strictly) increasing function is (strictly) increasing. Note that $x^{2n+1}$ has positive derivative and it is bijective. Its inverse is your function $f$.
[ If $g$ is strictly incerasing, $x<y$ and $g^{-1}(x) geq g^{-1}(y)$ then $g(g^{-1}(x)) geq (g^{-1}(y))$ which is a contradiction. Hence $g^{-1}(x) < g^{-1}(y)$].
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
answered Dec 9 at 12:11
Kavi Rama Murthy
49.8k31854
49.8k31854
add a comment |
add a comment |
As you recognised, the claim is true if and only if $f_n(x):=x^{1/(2n+1)}$ is monotonously increasing. However this is not true. For the sake of convenience set $m=1/(2n+1)$, then
$$frac{d}{dx}f_n(x)=mx^{m-1}$$
which needs to be always positive for $f_n$ to be monotonously increasing. Let's restrict the domain to $(0,infty)$ to avoid complications with negative powers. Note that anywhere in this domain, $x$ raised to anything is always positive, hence $f_n'$ is positive iff $m$ is. So let's pick $m=-1$ (corresponding to $n=-1$) or any negative number to achieve $f_n'<0$ for all $x$, at which point we get $f_{-1}(x)=1/x$, a decreasing function on $(0,infty)$. Thus the problem condition is true exactly when $m>0$; or in other words, $n>0$.
Edit: in the comments you said that $ninmathbb N$, which of course implies $n>0$. Hence, the claim is true.
answered Dec 9 at 12:18
YiFan
2,4391421
add a comment |
As you recognised, the claim is true if and only if $f_n(x):=x^{1/(2n+1)}$ is monotonously increasing. However this is not true. For the sake of convenience set $m=1/(2n+1)$, then
$$frac{d}{dx}f_n(x)=mx^{m-1}$$
which needs to be always positive for $f_n$ to be monotonously increasing. Let's restrict the domain to $(0,infty)$ to avoid complications with negative powers. Note that anywhere in this domain, $x$ raised to anything is always positive, hence $f_n'$ is positive iff $m$ is. So let's pick $m=-1$ (corresponding to $n=-1$) or any negative number to achieve $f_n'<0$ for all $x$, at which point we get $f_{-1}(x)=1/x$, a decreasing function on $(0,infty)$. Thus the problem condition is true exactly when $m>0$; or in other words, $n>0$.
Edit: in the comments you said that $ninmathbb N$, which of course implies $n>0$. Hence, the claim is true.
answered Dec 9 at 12:18
YiFan
2,4391421
add a comment |
As you recognised, the claim is true if and only if $f_n(x):=x^{1/(2n+1)}$ is monotonously increasing. However this is not true. For the sake of convenience set $m=1/(2n+1)$, then
$$frac{d}{dx}f_n(x)=mx^{m-1}$$
which needs to be always positive for $f_n$ to be monotonously increasing. Let's restrict the domain to $(0,infty)$ to avoid complications with negative powers. Note that anywhere in this domain, $x$ raised to anything is always positive, hence $f_n'$ is positive iff $m$ is. So let's pick $m=-1$ (corresponding to $n=-1$) or any negative number to achieve $f_n'<0$ for all $x$, at which point we get $f_{-1}(x)=1/x$, a decreasing function on $(0,infty)$. Thus the problem condition is true exactly when $m>0$; or in other words, $n>0$.
Edit: in the comments you said that $ninmathbb N$, which of course implies $n>0$. Hence, the claim is true.
answered Dec 9 at 12:18
YiFan
2,4391421
As you recognised, the claim is true if and only if $f_n(x):=x^{1/(2n+1)}$ is monotonously increasing. However this is not true. For the sake of convenience set $m=1/(2n+1)$, then
$$frac{d}{dx}f_n(x)=mx^{m-1}$$
which needs to be always positive for $f_n$ to be monotonously increasing. Let's restrict the domain to $(0,infty)$ to avoid complications with negative powers. Note that anywhere in this domain, $x$ raised to anything is always positive, hence $f_n'$ is positive iff $m$ is. So let's pick $m=-1$ (corresponding to $n=-1$) or any negative number to achieve $f_n'<0$ for all $x$, at which point we get $f_{-1}(x)=1/x$, a decreasing function on $(0,infty)$. Thus the problem condition is true exactly when $m>0$; or in other words, $n>0$.
Edit: in the comments you said that $ninmathbb N$, which of course implies $n>0$. Hence, the claim is true.
answered Dec 9 at 12:18
YiFan
2,4391421
answered Dec 9 at 12:18
YiFan
2,4391421
answered Dec 9 at 12:18
YiFan
2,4391421
answered Dec 9 at 12:18
YiFan
2,4391421
2,4391421
add a comment |
add a comment |
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If $frac{1}{2n + 1}$ is a constant you might find it easier just to call that $t$ or something.
– Trevor Gunn
Dec 9 at 7:18
@TrevorGunn;How would that help?
– Join_PhD
Dec 9 at 7:19
Then you're less focused on the having a fraction in your exponent and you can think about the general properties of $x^t$ where $0 < t < 1$.
– Trevor Gunn
Dec 9 at 7:22
Is $x$ assumed to be positive? And what variable denotes $n$?
– Dr. Sonnhard Graubner
Dec 9 at 9:37
X is a real number and n is constant natural number
– Join_PhD
Dec 9 at 9:43